Floating community

ABSTRACT

A sustainable floating community based on a mass-produced modular, pre-fabricated kit of parts referred to as floating modular units. The floating modular units are designed to allow for various needs while remaining simple to deliver and assemble by hand in remote destinations prone to volatile shifts in water levels and currents. The floating modular units are ready to assemble, can be erected for use on land and bodies of water, are easily collapsible for transport, thereby serving as highly adaptable transportable structures.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit of U.S. Provisional Application No.62/176,421 filed Feb. 18, 2015, which is hereby incorporated byreference in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to communities. More particularly, thepresent invention relates to communities produced from modular,pre-fabricated kits that are easily delivered and assembled and designedfor a variety of configurations for water and land.

2. Background

Communities around the world in remote or non-remote locations, live inareas adversely affected by volatile changes in water levels prone toseasonal or frequent flooding as a result of unpredictable extreme waterlevel fluctuations. People living along rivers are faced with having toreside above water for at least eight months out of the year. With only4 months of dry season with exposed ground, opportunities to raiseanimals for sustenance are very limited causing cycles of poverty. Withfrequent flooding, water levels may rise or recede up to 30 feet in thespan of a few days. Existing local construction materials andconstruction technology is very limited increasing time spent makingcontinuous repairs and rebuilding.

These communities currently lack adequate electrical power, sanitationand clean drinking water which adversely affects the population andinsures the communities' continual battle with poverty. These existingconditions demonstrate an overwhelming lack of suitable materials andtechnology to provide long-term protection, safety, comfort and means ofbecoming economically self-sufficient.

As such, there is a need for a self-contained, floating modular systemwhich can be arranged in a variety of configurations that is easilydeliverable and assembled. These modular systems allow people from thesecommunities to have access to a sustainable lifestyle by meeting thevarious living, working, playing programs that their livelihood dependson when living on or directly adjacent to the water. By creatingsustainable floating communities where public utilities are notavailable and allowing users to have safe housing, the ability to farm,grow livestock, educate, conduct commerce, provide medical proceduresand many other life-essential uses, the self-contained, floating modularsystem is directed toward providing such a technique to insure a moreadequate lifestyle and means to accomplish a better way of life. Thedurable and flexible nature of the invention allows the invention tofunction on both water and land to best meet the fluctuating waterlevels and other local site conditions with relative ease.

SUMMARY

According to an embodiment of the present invention, there istransportable structure kit for use in assembling floatable communitiesin a variety of configurations, comprising: a pair of floatable exteriorcontainer shells attachable to each other to form an enclosedtransportable container in a transportation mode, the pair of exteriorcontainer shells separable as a top portion shell and a bottom portionshell, and at least one exterior side of the bottom portion shellconfigured for detachably fastening to at least one floating platform; aplurality of column members detachably mounted between the top portionshell and the bottom portion shell in at least four corners of eachshell, securing the top portion shell apart from the bottom portionshell in an assembled mode; and a plurality of panel sections detachablymounted between the bottom portion shell and the top portion shell inthe assembled mode. The plurality of column members and plurality ofpanel sections are configured for repetitive assembly and disassembly,and entirely storable within the transportable container in thetransportation mode. The structure of the kit in assembled form isfloatable. The structure is attachable to each other via one or morefloating platforms, such that a floating community is formed.

According to another embodiment of the present invention, there is atransportable structure kit for use in assembling floatable communitiesin a variety of configurations, comprising: a roof section and a hullsection attachable to each other to form an enclosed container in apacked form, each hull section having at least four sides wherein atleast one side is removably connectable to at least one independentlyfloatable platform; a plurality of column members detachably mountablebetween the roof section and the hull section, forming a height oflivable space between the roof section and the hull section in anassembled form; a plurality of panel sections detachably mountablebetween the roof section and the hull section; and a photovoltaic systemcoupled to the roof section. The column members, panel sections andphotovoltaic system are storable inside the enclosed container formed bythe roof section and the hull section during the packed form.

According to yet another embodiment of the present invention, there is amethod of making a floatable shelter structure from a transportablestructure kit, where the kit comprises a pair of exterior containershells attachable to each other to form an enclosed transportablecontainer, the pair of exterior container shells separable as a roofportion and a hull portion, and one or more exterior sides of the hullportion configured for detachably fastening to at least one floatingplatform; a plurality of detachably mountable column members; and aplurality of detachably mountable panels. The method comprises laying aplurality of platforms adjacent to one another in a hull; connecting atleast one first end of a column member to a hull of the shelterstructure; connecting at least one second end of a column member to aroof of the shelter structure; connecting at least one floating platformto at least one side of the hull; and connecting at least one panel to amounting track and fastening the at least one floating platform to atleast one exterior side of the hull portion.

These features, advantages and other embodiments of the presentinvention are further made apparent, in the remainder of the presentdocument, to those of ordinary skill in the art.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more fully describe embodiments of the present invention,reference is made to the accompanying drawings. These drawings are notto be considered limitations in the scope of the invention, but aremerely illustrative.

FIG. 1 is a perspective view of a packed floating module unit (FMU)ready for delivery, according to an embodiment of the present invention.

FIG. 2 is a perspective view of a single floating module unit (FMU) withadjacent floating pontoon walkway, according to an embodiment of thepresent invention.

FIG. 3 is a perspective view of an open FMU, according to an embodimentof the present invention.

FIG. 4 is a perspective view of an open FMU with partially visible kitof parts contents, according to an embodiment of the present invention.

FIG. 5 is a perspective view of one FMU with floor decking in anassembly state, according to an embodiment of the present invention.

FIG. 6 is an exploded perspective view of the components of a FMU andthe packing nature of a FMU, according to an embodiment of the presentinvention.

FIG. 7 is a perspective view of one FMU with erected column and cornermold claddings in an assembly state, according to an embodiment of thepresent invention.

FIG. 8 is a perspective view of one FMU with erected column and cornermold cladding, modular fiberglass mold top cap and integratedphotovoltaic panel in an assembly state, according to an embodiment ofthe present invention.

FIG. 9 is an exploded perspective view of the assembly nature of a FMUand its components, according to an embodiment of the present invention.

FIG. 10 is a perspective view of one FMU with erected column and cornermold cladding, modular fiberglass mold top cap with integratedphotovoltaic panel, floating pontoons and interlocking guardrails,according to an embodiment of the present invention.

FIG. 11 is a perspective view of one FMU with erected column and cornermold cladding, modular fiberglass mold top cap with integratedphotovoltaic panel, floating pontoons, interlocking guardrails andgroove wall panel cladding, according to an embodiment of the presentinvention.

FIG. 12 is a perspective view showing a fully assembled FMUconfiguration, according to an embodiment of the present invention.

FIG. 13 is a detail sectional view of connection details between FMU andfloating pontoon assembly, according to an embodiment of the presentinvention.

FIG. 14 is a perspective view of three FMU attached to a floatingpontoon plaza to create a larger assembly, according to an embodiment ofthe present invention.

FIG. 15 is a top plan view of three FMU attached to a floating pontoonplaza to create a larger assembly of an open air floating pontoon plaza,according to an embodiment of the present invention.

FIG. 16 is a perspective view of three FMU attached to a floatingpontoon plaza covered with an erect waterproof tensile fabric canopy,according to an embodiment of the present invention.

FIG. 17 is a sectional view thru a three FMU and floating pontoonassembly with erected tensile fabric canopy, according to an embodimentof the present invention.

FIG. 18 is a top plan view of the three FMU attached to a floatingpontoon plaza covered with an erect waterproof tensile fabric canopy,according to an embodiment of the present invention.

FIG. 19 is a sectional view thru a FMU and floating pontoon assembly,according to an embodiment of the present invention.

FIG. 20 is a perspective view of six FMU and floating pontoon assemblywith two erected tensile fabric canopies conjoined to create a largerwater-proof composition, according to an embodiment of the presentinvention.

FIG. 21 is a sectional view thru six FMU and floating pontoon assemblywith erected tensile fabric canopy, according to an embodiment of thepresent invention.

FIG. 22 is a top plan view of six FMU and floating pontoon assembly,according to an embodiment of the present invention.

FIG. 23 is a plan view at the main deck level of six FMU and floatingpontoon assembly, according to an embodiment of the present invention.

FIG. 24 is a bottom plan view below the deck level of six FMU andfloating pontoon assembly and its components, according to an embodimentof the present invention.

FIG. 25 is a perspective view of ten FMU and larger floating pontoonassembly with six erected tensile fabric canopies conjoined to create alarger water-proof assembly area suitable for a plurality of uses,according to an embodiment of the present invention.

FIG. 26 is a perspective view of eight modified open sided FMU and twoenclosed FMU and a larger floating pontoon assembly conjoined to createan open air assembly suitable for livestock or plurality of uses,according to an embodiment of the present invention.

FIG. 27 is a perspective view showing eight modified open sided FMU andtwo enclosed FMU and a larger floating pontoon assembly with six erectedtensile fabric canopies conjoined to create a water-proof and protectedassembly suitable for livestock or plurality of uses, according to anembodiment of the present invention.

FIG. 28 is a sectional view thru a ten FMU and floating pontoon assemblywith six erected tensile fabric canopies, according to an embodiment ofthe present invention.

FIG. 29 is a plan view at the main deck level of ten FMU and a largerfloating pontoon assembly conjoined to create a larger assembly areasuitable for a plurality of uses, according to an embodiment of thepresent invention.

FIG. 30 is a top plan view of ten FMU and a larger floating pontoonassembly with six erected tensile fabric canopies conjoined to create alarger water-proof assembly area suitable for a plurality of uses,according to an embodiment of the present invention.

FIG. 31 is a top plan view at deck level of eight modified open sidedFMU and two enclosed FMU and a larger floating pontoon assembly with sixerected tensile fabric canopies conjoined to create a water-proof andprotected assembly suitable for livestock or plurality of uses,according to an embodiment of the present invention.

FIG. 32 is a perspective view of ten FMU and a larger floating pontoonassembly conjoined to create a larger assembly area suitable for aplurality of uses, according to an embodiment of the present invention.

FIG. 33 is a bottom plan view below the deck level of ten FMU and alarger floating pontoon assembly conjoined to create a larger assemblyarea suitable for a plurality of uses and its components, according toan embodiment of the present invention.

FIG. 34 is a perspective view of five modified open sided FMU and oneenclosed FMU and a larger floating pontoon assembly conjoined to serveas an open air floating aquaponics farm, according to an embodiment ofthe present invention.

FIG. 35 is a perspective view of five modified open sided FMU and oneenclosed FMU and a larger floating pontoon assembly with two erectedtransparent tensile fabric canopies conjoined to serve as an enclosedfloating aquaponics farm, according to an embodiment of the presentinvention.

FIG. 36 is a sectional view thru five modified open sided FMU and oneenclosed FMU and a larger floating pontoon assembly with two erectedtensile fabric canopies conjoined to serve as an enclosed floatingaquaponics farm, according to an embodiment of the present invention.

FIG. 37 is a top plan view of five modified open sided FMU and oneenclosed FMU and a larger floating pontoon assembly with two erectedtransparent tensile fabric canopies conjoined to serve as an enclosedfloating aquaponics farm, according to an embodiment of the presentinvention.

FIG. 38 is a top plan view at deck level of five modified open sided FMUand one enclosed FMU and a larger floating pontoon assembly with twoerected transparent tensile fabric canopies conjoined to serve as anenclosed floating aquaponics farm, according to an embodiment of thepresent invention.

FIG. 39 is a perspective view of a series of floating pontoon assemblyconfigured to create a large open air plaza, according to an embodimentof the present invention.

FIG. 40 is a perspective view of eight enclosed FMU attached to a seriesof floating pontoon assembly and eighteen underwater fish basinsconjoined to function as a fish farm, according to an embodiment of thepresent invention.

FIG. 41 is a perspective view showing various FMU configurationsarranged and attached to each other to create a floating community,according to an embodiment of the present invention.

FIG. 42 is a top plan view of various FMU configurations arranged andattached to create a floating community, according to an embodiment ofthe present invention.

DETAILED DESCRIPTION OF SPECIFIC EMBODIMENTS

The description above and below and the drawings of the present documentfocus on one or more currently preferred embodiments of the presentinvention and also describe some exemplary optional features and/oralternative embodiments. The description and drawings are for thepurpose of illustration and not limitation. Those of ordinary skill inthe art would recognize variations, modifications, and alternatives.Such variations, modifications, and alternatives are also within thescope of the present invention. Section titles are terse and are forconvenience only.

FIG. 1 is a perspective view of a packed floating module unit (FMU) 18ready for delivery, according to an embodiment of the present invention.FIG. 1 illustrates the compact nature of all the components fitting intothe shell of the modular fiberglass mold hull 20 and modular fiberglassmold top cap 60. The overall dimensions of a packed FMU 18 prior toassembly are designed to fit within typical cargo shipping containersand most shipping trucks for ease of transport to final destination.According to an embodiment, the dimension of a packed FMU 18 isapproximately 2300 millimeters×4600 millimeters×1130 millimeters. Otherdimensions of a packed FMU are contemplated and which can meet cargoshipping container parameters. As the packed FMU 18 is delivered to asite, users can begin to unpack and pull out all components necessary.The modular mounting track 50 and modular mounting corner track 51 arebuilt into the packed FMU 18 and provide a support to attach and securewall paneling. As shown, the modular mounting tracks 50 and modularmounting corner tracks 51 may be preinstalled on the surroundingexterior perimeter of the mold hull 20 and mold top cap 60. Moreover, inother embodiments, the tracks 50, 51 may instead be packed inside theFMU for subsequent installation onto the hull 20 and top cap 60; or foradditional installation to other locations or as replacements pieces.When transporting, the mold top cap 60 and mold hull 20 are securedtogether by the modular mounting track 50 and the modular mountingcorner track 51 with a fastening assembly, for example, a bolt and nutconnection.

FIG. 2 is a perspective view of an assembled single floating module unit(FMU) 19 with adjacent high density polyethylene-interlocking floatationpontoon modules (IFPM) walkways 138, according to an embodiment of thepresent invention. A single FMU 19 can function as a single floatingenclosed space, or it can be modified to have open sidewalls. An FMU 19may be attached to other FMU 19 or high densitypolyethylene-interlocking floatation pontoon modules (IFPM) 140 with orwithout waterproof tensile fabric canopies 109 (not shown) or 110 (notshown) to allow for larger enclosed areas. The FMU 19 derives itsflotation attributes (floatability) from the modular fiberglass moldhull 20 and the stability of the FMU 19 is enhanced by utilizingcommercially available IFPM 140. IFPM 140 is secured to other IFPM 140by a pontoon connector pin 142. A hinge plate connector 47 securelyconnects the FMU 19 with the IFPM 140. The FMU 19 can be connected toother FMU 19 in various configurations to create additional surface areato provide better stabilizing properties to help counter water and wavemotion. For example, the FMU 19 can be connected directly to another FMU19 using a similar hinge plate connector 47 (not shown) as that usedbetween an FMU 19 and the IFPM 140. The FMU 19 is also secured by theinterlocking guardrails 143 located on the surface of the IFPM 140.

The FMU 19 provides protection from weather conditions by use of anoverhead modular fiberglass mold top cap 60 and the tongue and groovewall panel cladding system-long 32 or clear glazing wall panel 38. TheFMU 19 design is flexible to accommodate a plurality of wall systemsthat can be inserted into the modular mounting track 50 and modularmounting corner track 51 and is structured by several fiberglassreinforced plastic structure columns 33. The fiberglass reinforcedplastic structure columns 33 have finishing material such as thefiberglass corner mold-outside edge 31. The tongue and groove fiberglassplatform flooring 44 is arranged side by side on top of a system offloor beams 43 (not shown), spanning the modular fiberglass mold hull20. A lower access hatch 29 is integrated into the flooring system toallow direct access to the photovoltaic system battery 22 (not shown),photovoltaic system inverter 23 (not shown) and polyethylene watercistern and purification module 28 (not shown) stored underneath the FMU19. The FMU 19 as illustrated also integrates the use of integratedphotovoltaic panels 70 to help aid in the production of electricity forthe intended use of the FMU 19.

FIG. 3 is a perspective view of an open packed FMU 18, according to anembodiment of the present invention. The highly durable nature of themodular fiberglass mold hull 20 and modular fiberglass mold top cap 60when secured together for transport to destination make the systemcompact and resistant to moisture, insects and rodents. As noted, themold hull 20 and the mold top cap 60 are secured at its respectivemodular mounting track 50 and the modular mounting corner track 51, forexample by a bolt connection (not shown) (see connection 301 in FIG. 13as an example connection). A simple assembly process by two persons isneeded and no need for tools beyond screwdrivers and a typical ratchetset. All the components fit in the modular fiberglass mold hull 20.Corner column insert sleeve 21 makes it easy for the user to attachfiberglass reinforced plastic-structure column 33 to the modularfiberglass mold hull 20. A corner column insert sleeve 21 may beconfigured on each of four corners of the hull 20.

FIGS. 4 and 5 are perspective views showing a packed FMU 18 beingunpacked-showing partially visible kit of parts contents including thetongue and groove fiberglass platform flooring 44 and integrated loweraccess hatch 29 that allow users to access crawl space. FIG. 4 furtherillustrates the door assembly 45 used by the user to enter and exit aFMU 19.

FIG. 6 is an exploded perspective view of the components of a packed FMU18, according to an embodiment of the present invention. All thenecessary components fit within the modular fiberglass mold hull 20 andthe modular fiberglass mold top cap 60 and these two items can act as asingle container for all the FMU 18 contents. The overall size,dimensions and stackable nature of the packed FMU 18 system is designedto fit within existing intermodal freight containers for ease oftransport to all destinations via ship, truck or plane. The contents ofthe packed FMU 18 comprise the photovoltaic system inverter 23,photovoltaic system battery 22, tongue and groove fiberglass platformflooring 44 with lower access hatch 29, wall panel bracket 37, clearglazing wall panel 38, column sleeve insert 21 modular mounting cornertrack 51, modular mounting track 50, fiberglass corner mold-inside edge30, fiberglass corner mold-outside edge 31, floor beams 43, fiberglassreinforced plastic structure column 33, tongue and groove wall panelcladding—long 32, door assembly 45, polyethylene water cistern andpurification module 28, and integrated photovoltaic panel 70. Themodular fiberglass mold top cap 60 and hull 20 are designed with amodular mounting corner track 51 and modular mounting track 50 included,which allows the attachment of various wall systems.

FIG. 7 is a perspective view of one packed FMU 18 with fiberglassreinforced plastic structure column 33 and fiberglass corner mold-inside30 and fiberglass corner mold-outside 31 in an assembly state, accordingto an embodiment of the present invention. FIG. 7 illustrates fiberglassreinforced plastic structure column 33 getting inserted into the cornercolumn insert sleeve 21 (not shown) via a cavity connection. Then eachfiberglass reinforced plastic structure column 33 is wrapped with afiberglass corner mold-inside edge 30 and fiberglass corner mold-outsideedge 31 that inserts into a modular mounting corner track 51 that isinserted into the modular fiberglass mold hull 20 for additionalprotection and stability.

FIG. 8 illustrates a roof is provided to the FMU 19 by attaching themodular fiberglass mold top cap 60 with the modular mounting track 50and modular mounting corner track 51 to the fiberglass reinforcedplastic structure column 33 and fiberglass corner mold-inside edge 30and fiberglass corner mold-outside edge 31.

FIG. 9 is an exploded perspective view of the assembly nature of a FMU19 and its components, according to an embodiment of the presentinvention. The lower portion of the FMU 19 is comprised of the modularfiberglass mold hull 20 which acts much like a hull for a boat. Thetongue and groove fiberglass platform flooring 44 comprises a loweraccess hatch 29 which allows users to access the storage space below andaccess to the photovoltaic system battery 22 (not shown), photovoltaicsystem inverter 23 (not shown), polyethylene water cistern (not shown)and purification module 28 (not shown). This pre-fabricated tongue andgroove fiberglass flooring will serve as the walking surface for usersand is highly durable and well suited for marine environments.

The FMU walls are erected by placing fiberglass reinforced plasticstructure columns 33 directly into the corner column insert sleeves 21within the modular fiberglass mold hull 20. Once these columns areerected, tongue and groove wall panel cladding—long 32 and fiberglasscorner mold-outside edge 31 are inserted into modular mounting track 50and modular mounting corner track 51 along the modular fiberglass moldhull 20 and modular fiberglass mold top cap 60 and held together in aninterlocking nature for stability. The modular fiberglass mold hull 20and modular fiberglass mold top cap 60 work together to lock the wallassembly and system together without the need for additional fastenersand the entire system can be erected with as little as two people. Theperimeter edge of the FMU 19 is designed to accommodate commerciallyavailable IFPM 140 systems and is directly connected to the FMU by ahinge plate connector 47 that allows the FMU 19 and IFPM 140 to besecurely connected while allowing acceptable range of motion tocounteract water motion and wave fluctuations. Pontoon connector pins142 connect the IFPM 140 to other IFPM 140.

FIG. 10 illustrates IFPM 140 attached to the outer edge of the FMU 19and bolted to the perimeter edge of the modular fiberglass mold hull 20by means of a hinge plate connector 47. The use of a hinge plateconnector 47 allows users to quickly attach or detach adjacent FMU 19 asneeded while providing necessary range of motion between FMU 19 tocounteract the typical wave and kinetic water motion. The perimeteredges of the IFPM 140 that are not attached to FMU 19 can include aninterlocking guardrail 143 for user safety.

FIGS. 11 and 12 illustrates assembling the wall system for an enclosedFMU 19. Tongue and groove wall panel cladding-long 32 composed ofdurable fiberglass are tilted and easily inserted and locked into placeby the modular mounting track 50. The tongue and groove mechanism ofeach wall panel allows panels to connect and lock-into place with eachother as well. The interlocking mechanism of both the modular mountingtrack 50 and tongue and groove connection type of the wall panels allowsfor a durable, rigid wall system requiring no additional bolts orfasteners. In instances where additional natural light is desired, aclear glazing panel system 38 can be substituted for the tongue andgroove wall panel cladding-long 32. A fully enclosed FMU 19 withintegrated photovoltaic panels 70 used for a plurality of uses isconstructed when all the paneling is in place. The flexible natureallows for FMU 19 to be assembled and arranged in a multitude ofconfigurations.

FIG. 13 is a detail sectional view of connection details between FMU 19and IFPM 140, according to an embodiment of the present invention. FIG.13 illustrates the floor beams 43 attaching to the modular fiberglassmold hull 20 by an angle bracket 302 and stainless steel bolt, washer,and nut assembly 301. Above the floor beam 43, rests the tongue andgroove fiberglass platform flooring 44. The perimeter edge of the IFPM140 not attached to an FMU 19 can have protective fence guardrail 36(not shown) to provide additional security for users.

FIG. 14 is a perspective view of three FMU 19 attached to a floatingpontoon plaza 144 to create a larger assembly, according to anembodiment of the present invention. As shown, the three FMU 19 areconnected to IFPM 140 using a hinge plate connector 47. A plurality ofIFPM 140 connected together using pontoon connector pin 142 create thepontoon plaza 144, which acts as a large central courtyard and canaccommodate larger program uses while also providing additionalstability to the overall assembly. The FMU 19 can be connected directlyto another FMU 19 using a hinge plate connector 47 (not shown).

FIG. 15 is a top plan view of three FMU 19 attached to a floatingpontoon plaza 144 to create a larger assembly of an open air floatingpontoon plaza 144, according to an embodiment of the present invention.Each FMU 19 is attached to a central courtyard of IFPM 140 by means of ahinge plate connector 47 that is bolted to the modular fiberglass moldhull 20 and IFPM 140. Each modular fiberglass mold top cap 60 provides asystem of integrated photovoltaic panels 70 to assist in the generationof power for the FMU 19. The pontoon connector pin 142 connects the IFPM140 to one another.

FIG. 16 is a perspective view of three FMU 19 attached to a floatingpontoon plaza 144 covered with an erect waterproof tensile fabric canopy110, according to an embodiment of the present invention. The additionof a waterproof tensile fabric canopy 110 covers the pontoon plaza 144and comprises a waterproof fabric sidewall with zipper 113. Thewaterproof tensile fabric canopy 110 attaches directly to the FMU 19 bywrapping around a fiberglass pipe 111 and inserting into a pre-moldedgap 114 or channel in the modular fiberglass mold top cap 60. Thefiberglass pipe 111 or tube is secured to the pre-molded gap 114 with amold fabric bracket 112 located on the top outer edge of the modularfiberglass mold top cap 60. In other methods, the fabric canopy 110 mayhave an edge sewn or otherwise fastened upon itself to form a cavity,through which the pipe 111 is fed through, and subsequently insertedinto the gap 114. The waterproof tensile fabric canopy—translucent 110can be used or not used depending on the user preference at that time.The fiberglass corner mold-outside edge 31 inserts into a modularmounting corner track 51 which is further inserted into the modularfiberglass mold hull 20 and modular fiberglass mold top cap 60 foradditional protection and stability.

FIG. 17 is a sectional view thru a three FMU 19 and floating pontoonplaza 144 with a waterproof tensile fabric canopy—translucent 110,according to an embodiment of the present invention. The illustrationshows waterproof tensile fabric canopy—translucent 110 elevated by thevertical canopy structural membrane 130 and the FMU 19 connected to thetwo adjacent FMU 19. The complete assembly is able to stay in place onthe water by means of an underwater restraint system comprising anelastic rode 52, which is connected to the steel U-bracket connector 55attached to the modular fiberglass mold hull 20 at one end and to thehelix anchor assembly 48 at the other end. The helix anchor assembly 48anchors into the earth and prevents the FMU 19 from floating away. Whenthe level of the water rises, the elastic rode 52 stretches allowing theFMU 19 and pontoon plaza 144 to rise along with the water level withoutgetting detached from the earth. When the level of the water decreases,the elastic rode 52 contracts allowing the FMU 19 and pontoon plaza 144to descend along with the water level without getting detached from theearth.

FIG. 17 further illustrates the floor beam 43 below the tongue andgroove fiberglass platform flooring 44. The waterproof tensile fabriccanopy-translucent 110 is supported by vertical canopy structuralmembers 130 connected to horizontal canopy structural members 132 by acanopy structural elbow connector 131. The waterproof tensile fabriccanopy-translucent 110 is connected to the FMU 19 by being wrappedaround a fiberglass pipe 111 and being secured to a pre-molded gap 114secured by a fiberglass top mold fabric bracket 112.

FIG. 17 further illustrates an integrated photovoltaic panel 70 on topof a modular fiberglass mold top cap 60 and a plurality of IFPM 140adjacent to one another to create a pontoon plaza 144.

FIG. 18 is a top plan view of the three FMU 19 attached to a floatingpontoon plaza 144 covered with an erect waterproof tensile fabriccanopy-translucent 110, according to an embodiment of the presentinvention. The addition of a waterproof tensile fabriccanopy—translucent 110 covers the pontoon plaza 144 and attachesdirectly to the FMU 19 by a fiberglass pipe 111 wrapping around thecanopy fabric and inserting this pipe into a pre-molded gap 114 (notshown) in the modular fiberglass mold top cap 60. This is firmly securedby placing a fiberglass top mold fabric bracket 112 over this assemblyand fastening directly to the modular fiberglass mold top cap 60 to keepthe canopy firmly secured to the FMU 19 while providing protection fromsun and rain.

FIG. 19 is a detailed sectional view thru a FMU 19 and floating pontoonplaza 144, according to an embodiment of the present invention. FIG. 19illustrates a hinge plate connector 47 connecting the IFPM 140 to themodular fiberglass mold hull 20 of the FMU 19. The tongue and groovefiberglass platform flooring 44 is held in place by the structural floorbeams 43 spanning the modular fiberglass mold hull 20 and angle brackets302. The roof is assembled by connecting the modular mounting track 50using stainless steel bolt, washer and nut assembly 301 onto the modularfiberglass mold top cap 60. The roof comprises built-in ventilationpockets 34 that allow air to penetrate while preventing water fromentering.

The pontoon plaza 144 can have additional roof coverage using thewaterproof tensile fabric canopy—translucent 110 that rolls around afiberglass pipe 111, while resting in a pre-molded gap 114 of themodular fiberglass mold top cap 60 and anchored above by a fiberglasstop mold fabric bracket 112.

FIG. 19 further illustrates the underwater restraint system comprisingthe elastic rode 52 connected to a steel U-bracket connector 55 andhelix anchor assembly 48 and fiberglass corner mold-inside edge 30 forfinishing the fiberglass reinforced plastic structure columns 33.

FIG. 20 is a perspective view of six FMU 19 and floating pontoon plaza144 with two erected waterproof tensile fabric canopy-translucent 110conjoined to create a larger water-proof composition, according to anembodiment of the present invention. FIG. 20 illustrates twoconfigurations displayed in FIG. 16 connected together by pontoonconnector pin 142 (not shown) to create a larger pontoon plaza 144 thatcan be utilized for a plurality of uses including but not limited tohousing, education, clinic, storage, assembly, church, and retail. Thewaterproof fabric sidewall with zipper 113 allows the user access toareas under the waterproof tensile fabric canopy-translucent 110 and FMU19 without having to be exposed to the elements. The wall of the FMU 19comprises tongue and groove wall panel cladding-long 32 removablyconnected to the modular mounting track 50 and modular mounting cornertrack 51. FIG. 20 further illustrates a perspective view of thefiberglass top mold fabric bracket 112 securing the waterproof tensilefabric canopy-translucent 110 to the FMU 19 and integrated photovoltaicpanel 70 secured to a modular fiberglass mold top cap 60.

FIG. 21 is a sectional view thru six FMU 19 and floating pontoon plaza144 with an erected waterproof tensile fabric canopy-translucent 110,according to an embodiment of the present invention.

FIG. 22 is yet another top plan view of six FMU 19 and floating pontoonplaza 144, according to an embodiment of the present invention. A FMU 19comprises an integrated photovoltaic panel 70 located on the modularfiberglass mold top cap 60. The integrated photovoltaic panel 70 can beinstalled on either the left or right side of the modular fiberglassmold top cap 60.

FIG. 23 is a plan view at the main deck level of six FMU 19 and floatingpontoon plaza 144, according to an embodiment of the present invention.FIG. 23 illustrates six FMU 19 along the perimeter of a pontoon plaza144. A FMU 19 can be considered a single room 200 or it can besubdivided into other uses such as a restroom area 220 and kitchen area210. An embodiment of the present invention utilizes a dry compostingtoilet in the restroom area 220 that uses an aerobic processing systemto treat human waste and the resultant compost to be used forhorticultural or agricultural soil enrichment. FIG. 23 furtherillustrates the layout of the waterproof fabric sidewall with zipper 113which allows an entry way between the FMU 19 and pontoon plaza 144. TheFMU 19 is connected to the pontoon plaza 144 by a hinge plate connector47. The user will have access to the level below the main deck throughthe lower access hatch 29. The FMU 19 can function as a dwelling unit,school or other suitable function. The uses of the FMU 19 tend to bemore private in nature while the large pontoon plaza 144 is more publicin nature and able to accommodate larger crowds of people.

FIG. 24 is a bottom plan view below the deck level of six FMU 19 andfloating pontoon plaza 144 and its components, according to anembodiment of the present invention. These components are located in themodular fiberglass mold hull 20 section of the FMU 19 and comprise thephotovoltaic system battery 22, photovoltaic system inverter 23, andpolyethylene water cistern and purification module 28. FIG. 24 furtherillustrates the plurality of pontoon connector pins 142 that connect theIFPM 140 to create the pontoon plaza 144 or IFPM walkways 138.

FIG. 25 is a perspective view of ten FMU 19 and larger floating pontoonplaza 144 comprising six erected waterproof tensile fabriccanopies-translucent 110 conjoined to create a larger water-proofassembly area suitable for a plurality of uses, according to anembodiment of the present invention.

FIG. 26 is a perspective view of eight open sided FMU 19 and twoenclosed FMU 19 and a larger floating pontoon plaza 144 conjoined tocreate an open air assembly suitable for livestock or plurality of uses,according to an embodiment of the present invention. Eight of the tenFMU 19 replace the wall paneling with a protective fence guardrail 36,however, the fiberglass corner mold-outside edge 31 is not removed. Alowered protective fence guardrail 36 keeps livestock safe within theopen sided FMU 19. These open sided FMU 19 also have native soil onfiberglass platform, flooring preferably used with livestock. A loweredprotective fence guardrail 36 to accommodate a larger livestock area onthe pontoon plaza 114 is also illustrated. The additional enclosed FMU19 can function as rooms, storage, restroom or additional needsdetermined by the user.

FIG. 27 is a perspective view showing eight open sided FMU 19 and twoenclosed FMU 19 and a larger floating pontoon plaza 144 with six erectedwaterproof tensile fabric canopies-translucent 110 conjoined to create awater-proof and protected assembly suitable for livestock or pluralityof uses, according to an embodiment of the present invention. Anembodiment of the present invention allows the floating pontoon plaza144 to be open to air as these canopies can easily erected or dismantledby people similar in the manner as a typical tent. The additionalenclosed FMU 19 can function as rooms, storage, restroom or additionalneeds determined by the user.

FIG. 28 is a sectional view thru a ten FMU 19 and floating pontoon plaza144 with six erected waterproof tensile fabric canopies-translucent 110,according to an embodiment of the present invention.

FIG. 29 is a plan view at the main deck level of ten FMU 19 and a largerfloating pontoon plaza 144 conjoined to create a larger assembly areasuitable for a plurality of uses, according to an embodiment of thepresent invention. The overall configuration can function as a dwellingunit, school or other suitable function. The uses of the FMU 19 asillustrated tend to be more private in nature while the large centralpontoon plaza 144 created by the IFPM 140 would be more public in natureand able to accommodate larger crowds of people.

FIG. 30 is a top plan view of ten FMU 19 and a larger floating pontoonplaza 144 with six erected waterproof tensile fabriccanopies-translucent 110 conjoined to create a larger water-proofassembly area suitable for a plurality of uses, according to anembodiment of the present invention.

FIG. 31 is a top plan view at deck level of eight open sided FMU 19 andtwo enclosed FMU 19 and a larger floating pontoon plaza 144 with sixerected waterproof tensile fabric canopies-translucent 110 conjoined tocreate a water-proof and protected assembly suitable for livestock orplurality of uses, according to an embodiment of the present invention.An advantage of an embodiment of the present invention is that it iseasily modified to accommodate native soil on fiberglass platformflooring 95, which works better with livestock. Eight of the ten FMU 19are open to air with lowered protective fence guardrails 36 along theperimeter of the pontoon plaza 144. This is to keep livestock secure intheir designated areas as the FMU-livestock 240 and two enclosed FMU 19are provided to allow an enclosed room and separate restroom area 220and kitchen area 210. The configuration shown could easily be considereda small farm or part of a larger farm if combined with additionalconfigurations. The configuration can be easily reduced, expanded oradded onto.

FIG. 32 is a perspective view of ten FMU 19 and a larger floatingpontoon plaza 144 conjoined to create a larger assembly area suitablefor a plurality of uses, according to an embodiment of the presentinvention. An advantage of the much larger surface area is that it willprovide more stability in the water while accommodating larger groups ofusers. Users will have access to the enclosed FMU 19 by the doorassembly 45. FIG. 32 illustrates how users can have both privacy andtogetherness through enclosed FMU 19 connected to a pontoon plaza 144.

FIG. 33 is a bottom plan view below the deck level of ten FMU 19 and alarger floating pontoon plaza 144 conjoined to create a larger assemblyarea suitable for a plurality of uses and its components, according toan embodiment of the present invention. These components comprisephotovoltaic system battery 22, photovoltaic system inverter 23, andpolyethylene water cistern and purification module 28. The corner columninsert sleeve 21, is a pre-molded cavity into the modular fiberglassmold hull 20 that accommodates a fiberglass reinforced plastic structurecolumn 33 (not shown).

FIG. 34 is a perspective view of five open sided FMU 19 and one enclosedFMU 19 and a larger floating pontoon plaza 144 conjoined to serve as anopen air floating aquaponics farm, according to an embodiment of thepresent invention. FIG. 25 shows the linear stacking nature of theaquaponics tank system 90 on the larger floating pontoon plaza 144 andthe open sided FMU 19 which allows users to be extremely efficient withrespect to horticulture needs. By placing these farming abilities in acontrolled, safe floating environment, users can extend the growingseason to continue without interruption. The configuration can bereduced, expanded or added to additional like or differentconfigurations based on user needs and requirements.

FIG. 35 is a perspective view of five modified open sided FMU 19 and oneenclosed FMU 19 and a larger floating pontoon plaza 144 with two erectedwaterproof tensile fabric canopy-clear/transparent 109 conjoined toserve as an enclosed floating aquaponics farm, according to anembodiment of the present invention. The transparent nature of thewaterproof tensile fabric canopy-clear/transparent 109 allowsphotosynthesis to occur for plant growth. Similar to FIG. 34, theillustration shows the linear stacking nature of the aquaponics tanksystem 90 which allows users to be extremely efficient with respect tohorticulture needs.

FIG. 36 is a sectional view thru five open sided FMU 19 and one enclosedFMU 19 and a larger floating pontoon plaza 144 with two erectedwaterproof tensile fabric canopy-clear/transparent 109 conjoined toserve as an enclosed floating aquaponics farm, according to anembodiment of the present invention. FIG. 36 illustrates the waterprooftensile fabric canopy-clear/transparent 109, is elevated by the verticalcanopy structural member 130 and connected to the outlying FMU 19 by ahinge plate connector 47 (not shown) with aquaponic tank system 90placed throughout the FMU 19 and floating pontoon plaza 144.

FIG. 37 is a top plan view of five open sided FMU 19 and one enclosedFMU 19 and a larger floating pontoon plaza 144 with two erectedwaterproof tensile fabric canopy-clear/transparent 109 conjoined toserve as an enclosed floating aquaponics farm, according to anembodiment of the present invention.

FIG. 38 is a top plan view at deck level of five open sided FMU 19 andone enclosed FMU 19 and a larger floating pontoon plaza 144 with twoerected waterproof tensile fabric canopy-clear/transparent 109 conjoinedto serve as an enclosed floating aquaponics farm, according to anembodiment of the present invention. The configuration shown alsoprovides an enclosed FMU 19 for restroom area 220 and kitchen area 210.

FIG. 39 is a perspective view of a series of floating IFPM 140configured to create a large open air pontoon plaza 144, according to anembodiment of the present invention. An embodiment of the presentinvention allows and accommodates the ability to vary the number of IFPM140 to create a plurality of size configurations to accommodate userneeds. The configuration illustrated in FIG. 39 like all preceding andfollowing configurations can be attached to other similar or dissimilarconfigurations to create a large community as seen in FIG. 41 or aplurality of other configurations based on user needs.

FIG. 40 is a perspective view of eight enclosed FMU 19 attached to aseries of floating pontoon plaza 144 and eighteen nylon netting fishbasin 100 conjoined to function as a fish farm, according to anembodiment of the present invention. These eighteen nylon netting fishbasin 100 create a fine water permeable mesh netting that allows thefish to remain in little fish pools that utilize existing water fromtheir natural habitat. These pools are accessed by the IFPM walkways138. The eight enclosed FMU 19 can be used for a plurality of usesincluding, but not limited to, cold storage, dry-fish storage, sleepingquarters, storage, restroom and kitchen.

FIG. 41 is a perspective view showing various FMU 19 configurationsarranged and attached to each other to create a floating community,according to an embodiment of the present invention. A plurality ofconfiguration can be created to meet the current and evolving needs ofits intended users while providing a more sustainable community. FIG. 41illustrates an overall floating masterplan of how the many previouslycited program configurations in the preceding figures are attached toone another by means of the IFPM 140 and hinge plate connector 47 tocreate a larger community while also allowing boat access to the manyperimeter edges. An additional layer of IFPM 140 stacked several layershigh can be added along the outermost perimeter edge to provideadditional security to the masterplan community similar to the outerwalls of a castle.

FIG. 42 is a top plan view of FIG. 41 illustrating various FMU 19configurations arranged and attached to create a floating community,according to an embodiment of the present invention. As shown, boataccess is provided to the many perimeter edges and locations throughoutthe community.

Throughout the description and drawings, example embodiments are givenwith reference to specific configurations. It will be appreciated bythose of ordinary skill in the art that the present invention can beembodied in other specific forms. Those of ordinary skill in the artwould be able to practice such other embodiments without undueexperimentation. The scope of the present invention, for the purpose ofthe present patent document, is not limited merely to the specificexample embodiments or alternatives of the foregoing description.

What is claimed is:
 1. A transportable structure kit for use inassembling floatable communities in a variety of configurations,comprising: a pair of floatable exterior container shells attachable toeach other to form an enclosed transportable container in atransportation mode, the pair of exterior container shells separable asa top portion shell and a bottom portion shell, and at least oneexterior side of the bottom portion shell bolted to a hinge plateconnector; the at least one exterior side of the bottom portion shelldetachably fastened to at least one floating platform by the hinge plateconnector; a plurality of column members detachably mounted between thetop portion shell and the bottom portion shell in at least four cornersof each shell, securing the top portion shell apart from the bottomportion shell in an assembled mode; a plurality of panel sectionsdetachably mounted between the bottom portion shell and the top portionshell in the assembled mode; wherein the plurality of column members andplurality of panel sections are configured for repetitive assembly anddisassembly, and entirely storable within the enclosed transportablecontainer in the transportation mode; at least one anchor assemblycomprising an elastic rode, a first end of the elastic rode connected toa helix anchor assembly and a second end of the elastic rode connectedto a bracket; the bracket attached to the exterior side of the bottomportion shell and the helix anchor assembly anchors into earth, whereinthe elastic rode contracts or stretches along with a change in waterlevel.
 2. The transportable structure kit of claim 1, wherein a set ofthe plurality of panel sections are detachably mounted horizontallyacross a top surface of the bottom portion shell as a floor in theassembled mode.
 3. The transportable structure kit of claim 2, furthercomprising a plurality of floor beams detachably mounted on the bottomportion shell beneath the floor, and wherein the plurality of floorbeams are entirely storable within the enclosed transportable containerin the transportation mode.
 4. The transportable structure kit of claim1, wherein a set of the plurality of panel sections are removablymounted vertically as a wall between the pair of exterior containershells in the assembled mode.
 5. The transportable structure kit ofclaim 1, wherein each exterior container shell is configured to have amounting track along an outer perimeter of the shell at or near alocation where the pair of exterior container shells meet when attachedin the transportation mode.
 6. The transportable structure kit of claim5, wherein a set of the plurality of panel sections are removablymounted as a wall to the mounting track of each of the pair of exteriorcontainer shells in the assembled mode.
 7. The transportable structurekit of claim 1, further comprising a plurality of column insert sleeves,one sleeve located near at least each corner of the bottom portionshell, configured to securely receive one of the plurality of columnmembers into the bottom portion shell.
 8. The transportable structurekit of claim 1, further comprising pre-manufactured components of thekit including: at least one photovoltaic system, finishing material, atrack system, hardware, insert sleeves, a battery, a water purificationsystem, floor support members, lighting, ventilation, and an anchoringsystem; wherein the components are entirely storable within the enclosedtransportable container in the transportation mode.
 9. The transportablestructure kit of claim 1, wherein the at least one floating platform isan interlocking floating pontoon module.
 10. The transportable structurekit of claim 1, wherein the at least one floating platform extending toconnect to a plurality of floating platforms to form a walkway.
 11. Thetransportable structure kit of claim 10, wherein an upper surface of thetop portion shell is configured to removably attach to a canopy, andwherein the canopy is removably attachable to the plurality of floatingplatforms by a set of support members.
 12. The transportable structurekit of claim 1, wherein the kit in an assembled form floats.
 13. Atransportable structure kit for use in assembling floatable communitiesin a variety of configurations, comprising: a roof section and a hullsection attachable to each other to form an enclosed container in apacked form, each hull section having at least four sides wherein atleast one side is bolted to a hinge plate connector; the at least oneside of the hull section removably connected to at least oneindependently floatable platform by the hinge plate connector; aplurality of column members detachably mountable between the roofsection and the hull section, forming a height of livable space betweenthe roof section and the hull section in an assembled form; a pluralityof panel sections detachably mountable between the roof section and thehull section; and a photovoltaic system coupled to the roof section;wherein the column members, panel sections and photovoltaic system arestorable inside the enclosed container formed by the roof section andthe hull section during the packed form; at least one anchor assemblycomprising an elastic rode, a first end of the elastic rode connected toa helix anchor assembly and a second end of the elastic rode connectedto a bracket; the bracket attached to the exterior side of the hullsection and the helix anchor assembly anchors into earth, wherein theelastic rode contracts or stretches along with a change in water level.14. The transportable structure kit according to claim 13, sized to fitinside a freight container when in the packed form.
 15. A plurality oftransportable structure kits according to claim 13, each transportablestructure kit in the assembled form attached to one or more interlockingfloating platforms and attached to another transportable structure kitin the assembled form via the one or more interlocking floatingplatforms.